Superconductor versus insulator in twisted bilayer graphene

We present a simple model that we believe captures the key aspects of the competition between superconducting and insulating states in twisted bilayer graphene. Within this model, the superconducting phase is primary, and arises at generic fillings, but is interrupted by the insulator at commensurat...

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Bibliographic Details
Published in:Physical review. B 2019-09, Vol.100 (11), p.1, Article 115128
Main Authors: Chou, Yang-Zhi, Lin, Yu-Ping, Sarma, Sankar Das, Nandkishore, Rahul M
Format: Article
Language:English
Subjects:
Bilayers
Cooper pairs
Couplings
Electrons
Graphene
Intersections
Phase diagrams
Quantum wires
Superconductivity
Superlattices
Wire
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Summary:We present a simple model that we believe captures the key aspects of the competition between superconducting and insulating states in twisted bilayer graphene. Within this model, the superconducting phase is primary, and arises at generic fillings, but is interrupted by the insulator at commensurate fillings. Importantly, the insulator forms because of electron-electron interactions, but the model is agnostic as to the superconducting pairing mechanism, which need not originate with electron-electron interactions. The model is composed of a collection of crossed one-dimensional quantum wires whose intersections form a superlattice. At each superlattice point, we place a locally superconducting puddle which can exchange Cooper pairs with the quantum wires. We analyze this model assuming weak wire-puddle and wire-wire couplings. We show that for a range of repulsive intrawire interactions, the system is superconducting at "generic" incommensurate fillings, with the superconductivity being "interrupted" by an insulating phase at commensurate fillings. We further show that the gapped insulating states at commensurate fillings give way to gapless states upon application of external Zeeman fields. These features are consistent with experimental observations in magic-angle twisted bilayer graphenes despite the distinct microscopic details. We further study the full phase diagram of this model and discover that it contains several distinct correlated insulating states, which we characterize herein.
ISSN:2469-9950
2469-9969
DOI:10.1103/PhysRevB.100.115128